Device and method for cutting out contours from planar substrates by means of laser

Abstract

A device for producing and removing an internal contour from a planar substrate comprising: a beam-producing- and beam-forming arrangement which is configured to perform: a contour definition step wherein a laser beam is guided over the substrate to produce a plurality of individual zones of internal damage in a substrate material along a contour line defining the internal contour; a crack deformation step, wherein the laser beam is guided over the substrate and produces a plurality of individual zones of internal damage in the substrate material to form a plurality of crack line portions that lead away from the contour line into the internal contour; and a material removal-step, wherein a laser beam directed towards the substrate surface that inscribes a removal line through a thickness of the substrate at the internal contour causes the internal contour to detach from the substrate.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of and claims priority to U.S. patent application Ser. No. 15/032,252, filed on Apr. 26, 2016, which claims the benefit of priority under 35 U.S.C. § 371 of International application Serial No. PCT/EP14/055364, filed on Mar. 18, 2014, which, in turn, claims the benefit of priority of European Application Serial No. 13160420.9, filed on Mar. 21, 2013, the contents of which are relied upon and incorporated herein by reference in their entirety.

BACKGROUND

The present invention relates to a device and to a method for cutting out contours from planar substrates (in particular: from glass substrates or crystal substrates) by means of laser.

DE 10 2011 00768 A1 describes how, with the help of a laser, semiconductor wafers, glass elements and other substrates can be divided into various parts by the wavelength of the laser being greatly absorbed by the material. As a result, material removal which leads finally to division of the substrate into a plurality of parts is effected. However, this method has disadvantages in the case of many materials, such as for example impurities due to particle formation during ablation or cut edges which have undesired microcracks or melted edges so that a cut gap which is not uniform over the thickness of the material is produced. Since in addition material must be vaporised or liquefied, a high average laser power must be provided.

Starting from the state of the art, it is therefore the object of the present invention to make available a method (and also a corresponding device) with which planar substrates, in particular made of brittle materials, can be machined with minimum crack formation at the edges, with as straight as possible cut edges and at a high process speed such that contours can be machined out from these substrates (and finally separated) without the result being undesired cracks, flaking or other disruptions which extend in the substrate plane remaining in the substrate after separation of the contours. Hence the aim of the present invention is exact, clean separation of a contour from a substrate, in particular clean, precise removal of internal contours from the substrate.

As is described subsequently in detail also, the operation takes place, according to the invention, generally with a pulsed laser at a wavelength for which the substrate material is essentially transparent. However, basically also the use of a continuous-wave laser is possible provided that the laser beam can be switched rapidly on and off again during guidance thereof over the substrate surface (e.g. by means of an optical modulator) in order to produce zones of internal damage situated one behind the other (see subsequently).

The object according to the invention is achieved by the methods and devices described herein.

Subsequently, the invention is first described in general, then with reference to embodiments. The features according to the invention produced within the scope of the embodiments need not thereby be produced precisely in the illustrated combinations within the scope of the invention but rather individual features can also be omitted or combined with other features in a different way. In particular, also features of different embodiments can be combined with each other or individual ones of the illustrated features can also be omitted.

Features of the method according to the invention are described in claims 1 and 13. The contour is thereby understood as a two-dimensional surface in the substrate plane in the form of a partial surface of the substrate. The portions of the substrate corresponding to this partial surface are intended to be removed from the substrate, the remaining portions of the substrate being intended to be further processed in subsequent processes. In other words: the contour to be separated from the substrate forms an undesired surface which can also be destroyed, the remaining substrate portions are intended to survive the separation process of the contour without internal damage and also with as ideal cut edges as possible according to the contour line. This is achieved according to the invention. Subsequently, there is/are thereby understood by the substrate, both the still unmachined substrate before separation of the contour and the remaining substrate remains after the separation of the contour. From the context respectively, the person skilled in the art knows what is intended.

According to the invention, the contour definition step is effected such that, after implementation thereof, the contour course of the contour is inscribed into the substrate material, however the contour is still connected to the substrate so that complete separation of the contour from the substrate is still not effected: the step-wise complete separation of the undesired contour from the substrate is effected by the contour definition step, the optional crack definition step, the optional stress-relieving step and the material removal- and/or material deformation step and, provided still required (i.e. if the contour remains do not independently already fall off by means of intrinsic stresses in the material after implementing steps (a) to (d)), by an optional aftertreatment step. Also the introduction of the individual zones of internal damage in the optional crack definition step and in the optional stress-relieving step is effected such that complete separation of the consequently produced partial portions in the substrate is still not effected.

Implementation of the optional crack definition step is effected preferably after conclusion of the contour definition step but this is not necessary: thus for example also partial portions of the contour line can be produced firstly by introducing the zones of internal damage before the crack definition step for producing the crack line portions is implemented and, after conclusion of the same, the remaining contour line portions of the contour definition step are introduced into the substrate material.

There is understood by the term of a crack line portion leading away from the contour line at an angle α>0°, that the angle α between the local tangent to the contour line at that place where the mentioned (possibly continued towards the contour line) crack line portion leads away from the contour line, and the local tangent at that end of the crack line portion, which is orientated towards the contour line, is greater than 0°.

According to the invention, the laser irradiation in steps (a), (b) and (d) (i.e. in the contour definition step, in the crack definition step and in the stress-relieving step—subsequently these terms (a) to (d) are also used alternatively for the steps according to the invention) need not be effected perpendicular to the substrate plane, i.e. the individual zones of internal damage need not extend perpendicular to the substrate plane (and also need not definitely pass through the entire substrate thickness perpendicular to the substrate plane). The laser irradiation can be effected also at an angle>0° (for example between 0° and 20°) relative to the substrate normal (inclined introduction of the zones of internal damage).

There are understood by the internal contours machined preferably within the scope of the invention (i.e. to be introduced and removed) simply coherent quantities of the two-dimensional space (plane of the substrate) or corresponding partial portions in the substrate, from a mathematical point of view. The internal contours to be removed therefrom can thereby have almost any shapes. In particular, circular shapes, ellipse shapes, pin-cushion shapes, oblong shapes (with rounded corners) etc. are possible for the internal contours, by the laser beam being moved on the substrate surface along a correspondingly shaped contour line. Preferably, the substrate is disposed thereby in a stationary manner within the world coordinate system and the laser beam is moved over the substrate surface by a suitable beam-guiding optical unit (which can have for example an F-theta lens followed by a galvanometer scanner). Alternatively, also a beam-guiding lens system which is stationary relative to the world coordinate system is possible, the substrate then requiring to be moved in the world coordinate system relative to the beam-guiding lens system and to the laser beam.

There is understood subsequently by substrate thickness, the extension of the substrate perpendicular to the substrate plane, i.e. between substrate front-side and the substrate rear-side. The substrate front-side is thereby that surface of the substrate which is orientated towards the radiated laser light.

The first preferably achieved features of the method according to the invention (material removal for introduction of a removal line) can be deduced.

This material removal can be applied in particular to large and small radii of internal contours to be separated and is suitable in particular for smaller contours, such as e.g. sections of a circle with a diameter<2.5 mm and for oblong holes.

For the material removal, a CO₂ laser with a beam diameter of in the range between approx. 0.05 mm and 0.5 mm, when impinging on the substrate (achieved by focusing) can be used. The CO₂ laser can be pulsed or applied continuously. Preferably, pulses in the range of 100 μs to 4,000 μs are used with pulse train frequencies of 0.1 kHz to 100 kHz. For particular preference, the pulse duration is in the range between 300 μs and 4,000 μs with 0.1 kHz to 3 kHz pulse train frequency. The laser power can be in the range of 10 to 200 W, preferably however in the range of 10 to 100 W.

The travel path of the laser beam is along the contour line, at a spacing from this and in the contour to be separated, for example therefore on a (parallel) trajectory symmetrical to the target contour. For example with a circular contour to be removed (hole section), a circular movement. The travel path can be performed either once or with multiple repetition.

Due to the small focus diameter and the high laser powers, the substrate material is primarily melted (material removal). Together with laser pulses in the upper microsecond range, the entire substrate material thickness (e.g. 0.7 mm) can thus be heated through completely with one pulse.

The material removal step can be assisted by the use of a gas nozzle with process gas (e.g. CDA). With for example a nozzle diameter of 2 mm and gas pressures of 1.5 to 4 bar, material removal can be produced particularly well even for small contours and radii. By means of the gas flow, the material melted by the laser is expelled in the beam direction.

With the above-described parameters, for example also toughened glasses (DOL 40 μm) can be supplied for material removal without the result being damaging crack formation.

The removal contour (removal line) should be removed sufficiently far from the contour line (target contour cut) (generally, spacings here of approx. 0.1 to 0.3 mm suffice, according to the substrate material): for example with a circular glass disc of 2 mm diameter which is to be removed, the minimum spacing of the removal line from the contour line should be 0.1 mm (deformation diameter or diameter of the circular removal line at most 1.8 mm). In the case of a glass sheet diameter of 1.5 mm, the deformation diameter should be at most 1.3 mm. In the case of a glass disc diameter of 1.0 mm, the deformation diameter should be at most 0.8 mm.

The crack line portions (e.g. V-cuts) which are described subsequently in more detail have an assisting effect for the complete separation of the contour.

According to the advantageous features of the disclosure, instead of one, or in addition to a material removal according to the disclosure, also removal of material portions of the contour to be separated is possible by means of thermal deformation.

A CO₂ laser or the laser beam thereof for extraction of substrate material in a manner which does not remove substrate material, i.e., can be used in a purely thermally deforming manner in substrate material (in particular of the contour to be separated) (this is effected preferably in the case of fairly large contours to be separated, e.g. in the case of circular sections with a diameter≥2.5 mm, preferably ≥5-10 mm, to be separated).

The procedure with such a material deformation step can be as follows:

By means of CO₂ laser irradiation of the substrate, e.g. by means of movement of the laser beam along the contour line but at a spacing therefrom and also in the contour to be separated (for example along a circle or a spiral in the centre of the contour to be separated), at least portions of the contour to be separated are heated such that the result is a plastic deformation of at least portions of the contour to be separated. The diameter of the CO₂ laser spot impinging on the substrate material can cover a wide range: 0.1 mm to 10 mm. A diameter of 0.2 mm to 3 mm is preferred. The CO₂ laser can be operated both pulsed and continuously. Preferably, however, pulses in the range of 6 μs to 4,000 μs are used with pulse train frequencies in the range of 0.1 kHz to 100 kHz. The laser power can be in the range between 10 and 300 W, preferably in the range between 10 and 50 W.

The travel path of the laser is preferably a trajectory which is symmetrical (e.g. parallel, but at a spacing) relative to the contour to be separated (target contour). For example in the case of a hole section as internal contour to be separated, a circular movement. However a spiral movement can also have a favourable effect on the thermoplastic deformation of such an internal contour (e.g. glass disc). In certain cases, it can prove to be favourable if the laser beam remains stationary over a defined time interval of for example 0.5 s simply in the centre of the contour to be separated and heats through and thus deforms the contour to be separated. The travel path can be covered either once or with multiple repetition which can have a favourable effect on the thermoplastic deformation of the contour to be separated.

The plastic deformation in the centre leads to shrinkage of the contour to be separated (e.g. glass disc) due to a thermally-induced flow of the substrate material (e.g. glass material) in the irradiated region in the centre and towards the centre. For example in the case of a circular disc as contour to be separated, this can be seen as follows:

• • The deformation generally forms, as a result of gravity, a bulge away from the laser in the direction of the centre of the earth. This bulge possibly can adopt a drop shape. The surface topography can be compared with that of a convex lens.
  • Under specific laser conditions, a bulge is also formed towards the laser. The surface topography is then that of a biconvex lens.
  • Under specific laser conditions, a dent (concave) is formed on one side and, on the opposite surface, a bulge.
  • If the irradiated surface is subjected to a flow of process gas (commercial air, CDA) in parallel and contemporaneously via a gas nozzle, the formation of the bulge and/or dent can be controlled very precisely. As a result, even contours with very small radii (<2.5 mm to 1.2 mm) can be introduced for the removal. In the case of for example a nozzle diameter of 2 mm and gas pressures in the range of 1.5 to −3 bar, relatively small contours can be particularly readily removed.

What the described thermoplastic deformation variants have in common is that substrate material of the contour to be separated flows (e.g. in the case of an internal contour to be removed flows towards the centre of the same) and consequently a gap relative to the remaining substrate material is formed (e.g. externally situated material of an internal contour to be removed). Such a gap can have dimensions of approx. 10 μm to 50 μm.

After a short thermal relaxation time (cooling and shrinkage of the contour to be separated), the contour to be separated falls out purely due to the forming gap.

In the case of the material deformation step, hence no substrate material is removed, no removal products are produced.

The CO₂-induced thermoplastic deformation or the regions irradiated by the laser should be removed sufficiently far (generally spacings of approx. 1 to 3 mm suffice according to the substrate material) from the already introduced contour line (contour cut): for example with a glass disc of 10 mm diameter to be removed, the region irradiated centrally in this glass disc (deformation diameter) should have a diameter of 8 mm at most. In the case of a glass disc diameter of 5 mm, this region should be 3.4 mm at most. In the case of a glass disc diameter of 2.5 mm, this region should be 1.5 mm at most.

The already introduced contour line (target contour cut) forms a sufficient thermal insulation relative to the surrounding material of the residual, remaining substrate so that, with suitable thermoplastic deformation diameter, no disadvantageous thermal effect on the cut edge or on the surrounding material in the form of chipping or parasitic crack formation can be effected.

In the subsequent embodiments, the material removal- and/or material deformation step as material removal step is effected by means a material-removing laser beam which is not illustrated in more detail.

Further preferably produced features can be deduced from the disclosure.

The ultrasonic treatment according to the disclosure can be effected as follows: frequency range between 1 kHz and 50 kHz (particularly preferred: 5 kHz-40 kHz). The surface in the interior of the cut contour (i.e. in the contour to be separated) is thereby preferably contacted with an ultrasonic actuator. The contact surface can thereby correspond to the dimensions and the shape of an internal contour to be separated. The contact can be implemented over the entire surface or as a ring. In a particular embodiment, substrate regions situated outside the contour to be separated can be treated with ultrasound (also simultaneous ultrasound treatment of the contour to be separated and such remaining substrate regions is possible).

A corresponding aftertreatment step is however frequently not required at all since the zones of internal damage, which are introduced in step (b) (and in the possibly implemented optional step (d)) already have internal stresses introduced into the substrate material which suffice for the undesired contour remains to be detached by themselves from the remaining substrate (self-removal of the contour remains) in the course of the material removal- and/or material deformation step or after the same.

Further advantageous achievable method features can be deduced from the disclosure.

All of the already described advantageous features and of the subsequently also described advantageous features can be produced thereby, within the scope of the invention, respectively individually or also in any combinations with each other.

The point focusing described in herein can thereby be implemented as described in U.S. Pat. No. 6,992,026 B2 or in WO 2012/006736 A2.

According to the invention, it is however particularly preferred to introduce the individual zones of internal damage along the contour line, the crack-line portions and possibly also the stress-relieving line portions by means of the laser beam focal line described in the disclosure (i.e. by induced absorption in the substrate material along an extended portion in the thickness direction of the material).

This preferred embodiment of step (a), (b) and (d) is now described subsequently in detail.

Firstly, it is thereby essential that the wavelength of the irradiating laser is chosen in coordination with the substrate to be machined such that the substrate material is essentially transparent for this laser wavelength.

The method for steps (a), (b) and (d) produces a laser focal line per laser pulse (in contrast to a focal point) by means of a laser lens system which is suitable for this purpose (subsequently also termed alternatively beam-guiding optical unit or optical arrangement). The focal line determines the zone of interaction between laser and material of the substrate. If the focal line falls into the material to be separated, then the laser parameters can be chosen such that an interaction with the material takes place and produces a crack zone along the focal line. Important laser parameters here are the wavelength of the laser, the pulse duration of the laser, the pulse energy of the laser and possibly also the polarisation of the laser.

For the interaction of the laser light with the material in steps (a), (b) and (d), there should preferably be the following:

• • 1) The wavelength λ of the laser is preferably chosen such that the material is essentially transparent at this wavelength (for example in concrete terms: absorption «10% per mm material depth=>γ«1/cm; γ: Lambert-Beer absorption coefficient).
  • 2) The pulse duration of the laser is preferably chosen such that, within the interaction time, no substantial heat transport (heat diffusion) from the interaction zone can take place (for example in concrete terms: τ«d²/α, d: focal diameter, τ laser pulse duration, α: heat diffusion constant of the material).
  • 3) The pulse energy of the laser is chosen preferably such that the intensity in the interaction zone, i.e. in the focal line, produces an induced absorption which leads to local heating of the material along the focal line, which in turn leads to crack formation along the focal line as a result of the thermal stress introduced into the material.
  • 4) The polarisation of the laser influences both the interaction on the surface (reflectivity) and the type of interaction within the material during the induced absorption. The induced absorption can take place via induced, free charge carriers (typically electrons), either after thermal excitation or via multiphoton absorption and internal photoionization or via direct field ionisation (field strength of the light breaks the electron bond directly). The type of production of the charge carriers can be assessed for example via the so-called Keldysh parameter (reference) which however plays no role in the application of the method according to the invention. In the case of specific (e.g. double-refracting materials), it can be important merely that the further absorption/transmission of the laser light depends upon the polarisation and hence the polarisation should be chosen favourably via suitable lens systems (phase plates) by the user for separation of the respective material, e.g. simply in a heuristic manner. If the substrate material is therefore not optically isotropic but for example double-refracting, then also the propagation of the laser light in the material is influenced by the polarisation. Therefore the polarisation and the orientation of the polarisation vector can be chosen such that, as desired, only one focal line and not two thereof are formed (ordinary and extraordinary beams). This is of no importance in the case of optically isotropic materials.
  • 5) Furthermore, the intensity should be chosen via the pulse duration, the pulse energy and the focal line diameter such that no ablation or melting but only crack formation in the structure of the solid body is effected. This requirement can be fulfilled for typical materials, such as glass or transparent crystals, most easily with pulsed lasers in the sub-nanosecond range, in particular therefore with pulse durations of e.g. between 10 and 100 ps. Above scale lengths of approx. one micrometre (0.5 to 5.0 micrometres), the heat conduction for poor heat conductors, such as for example glasses, acts into the sub-microsecond range, whilst, for good heat conductors, such as crystals and semiconductors, the heat conduction is effective even from nanoseconds onwards.

The essential process for forming the zones of internal damage, i.e. the crack formation in the material which extends vertically relative to the substrate plane, is mechanical stress which exceeds the structural strength of the material (compression strength in MPa). The mechanical stress is achieved here by rapid, non-homogeneous heating (thermally induced stress) due to the laser energy. The crack formation in steps (a), (b) and (d), provided there is corresponding positioning of the substrate relative to the focal line (see subsequently), of course starts on the surface of the substrate since the deformation is greatest there. This is because, in the half-space above the surface, there is no material which can absorb forces. This argument also applies for materials with toughened or prestressed surfaces as long as the thickness of the toughened or prestressed layer is large relative to the diameter of the suddenly heated material along the focal line (see, in this respect, also FIG. 1 which is also described subsequently).

The type of interaction can be adjusted via the fluence (energy density in joules per cm²) and the laser pulse duration with the chosen focal line diameter such that firstly no melting takes place on the surface or in the volume and secondly no ablation takes place with particle formation on the surface.

Subsequently, the production of the contour line of a desired separation surface (relative movement between laser beam and substrate along the contour line on the substrate surface), i.e. step (a), is described. The same applies to (b) and (d).

The interaction with the material produces, per laser pulse, an individual, continuous (viewed in the direction perpendicular to the substrate surface) crack zone in the material along a focal line. For complete separation of the material, a sequence of these crack zones per laser pulse is placed so closely to each other along the desired separation line that a lateral connection of the cracks to form a desired crack surface/contour is produced in the material. For this, the laser is pulsed at a specific train frequency. Spot size and spacing are chosen such that, on the surface along the line of the laser spots, a desired, directed crack formation begins. The spacing of the individual crack zones along the desired separation surface is produced from the movement of the focal line relative to the material within the timespan of laser pulse to laser pulse. See in this respect also FIG. 4 which is also described subsequently.

In order to produce the desired contour line or separation surface in the material, either the pulsed laser light can be moved with an optical arrangement which is moveable parallel to the substrate plane (and possibly also perpendicular thereto) over the stationary material or the material itself is moved past the stationary optical arrangement with a moveable receiving means such that the desired separation line is formed. The orientation of the focal line relative to the surface of the material, whether perpendicular or at an angle>0° relative to the surface normal, can be chosen either to be fixed or it can be changed via a rotatable optical normal arrangement (subsequently also termed lens system for simplification) and/or via a rotatable beam path of the laser along the desired contour line or separation surface or -line.

In total, the focal line for forming the desired separation line can be guided in up to five separately moveable axes through the material: two spatial axes (x, y) which fix the penetration point of the focal line into the material, two angular axes (theta, phi), which fix the orientation of the focal line from the penetration point into the material, and a further spatial axis (z′, not necessarily orthogonal to x, y), which fixes how deeply the focal line extends from the penetration point on the surface into the material. For the geometry in the Cartesian coordinate system (x, y, z), see also for example the subsequently described FIG. 3A. In the case of the perpendicular incidence of the laser beam on the substrate surface, z=z′ applies.

The final separation of the material (separation of the contour) along the produced contour line is effected either by inherent stress of the material or by introduced forces, e.g. mechanically (tension) or thermally (non-uniform heating/cooling). Since in steps (a), (b) and (d) no material is ablated, there is generally initially no continuous gap in the material but only a highly disrupted fracture surface (microcracks) which are interlocked per se and possibly also connected by bridges. As a result of the forces introduced subsequently in the aftertreatment step, the remaining bridges are separated via lateral (effected parallel to the substrate plane) crack growth and the interlocking is overridden so that the material can be separated along the separation surface.

The laser beam focal line which can be used in (a), (b) and (d) is termed, for simplification previously and subsequently, also focal line of the laser beam. In (a), (b) and (d), the substrate is prepared by the crack formation (induced absorption along the focal line which extends perpendicular to the substrate plane) with the contour line, the crackline portions and the stress-relieving line portion(s) for separation of the contour from the substrate. The crack formation is effected preferably perpendicular to the substrate plane into the substrate or into the interior of the substrate (longitudinal crack formation). As described already, generally a large number of individual laser beam focal lines must be introduced into the substrate along one line (e.g. contour line) on the substrate surface in order that the individual parts of the substrate can be separated from each other. For this purpose, either the substrate can be moved parallel to the substrate plane relative to the laser beam or to the optical arrangement or, conversely, the optical arrangement can be moved parallel to the substrate plane relative to the substrate which is disposed in a stationary manner.

The induced absorption of steps (a), (b) and (d) is advantageously produced such that the crack formation in the substrate structure is effected without ablation and without melting of the substrate material. This takes place by means of adjusting the already described laser parameters, explained subsequently also in the scope of examples, and also the features and parameters of the optical arrangement. The extension 1 of the laser focal line and/or the extension of the portion of the induced absorption in the substrate material (in the substrate interior) respectively, viewed in the beam longitudinal direction, can thereby be between 0.1 mm, preferably between 0.3 mm and 10 mm. The layer thickness of the substrate is preferably between 30 and 3,000 μm, particularly preferred between 100 and 1,000 μm. The ratio 1/d of this extension 1 of the laser beam focal line and the layer thickness d of the substrate is preferably between 10 and 0.5, particularly preferred between 5 and 2. The ratio L/D of the extension 1 of the portion of the induced absorption in the substrate material, viewed in the beam longitudinal direction, and of the average extension D of the portion of the induced absorption in the material, i.e. in the interior of the substrate, is preferably, viewed transversely relative to the beam longitudinal direction, between 5 and 5,000, particularly preferred between 50 and 5,000. The average diameter δ (spot diameter) of the laser beam focal line is preferably between 0.5 μm and 5 μm, particularly preferred between 1 μm and 3 μm (e.g. at 2 μm). The pulse duration of the laser should be chosen such that, within the interaction time with the substrate material, the heat diffusion in this material is negligible (preferably no heat diffusion is effected). If the pulse duration of the laser is characterised with τ, then there applies preferably for τ, δ and the heat diffusion constant β of the material of the substrate, τ«δ²/β. This means that τ is less than 1%, preferably less than 1% of δ²/β. For example, the pulse duration τ at 10 ps (or even below that) can be between 10 and 100 ps or even above 100 ps. The pulse repetition frequency of the laser is preferably between 10 and 1,000 kHz, preferably at 100 kHz. The laser can thereby be operated as a single pulse laser or as burst pulse laser. The average laser power (measured on the beam output side of the laser) is preferably between 10 watts and 100 watts, preferably between 30 watts and 50 watts for steps (a), (b) and (d).

In steps (a), (b) and (d), a laser beam is hence moved relative to the substrate surface along a line, along which a large number of individual zones of internal damage are to be introduced into the substrate (also termed extended portions of induced absorption in the interior of the substrate along the respective line). The ratio α/δ of the average spacing a of the centres of immediately adjacent zones of internal damage, i.e. produced directly after each other (portions of induced absorption) and the average diameter δ of the laser beam focal line (spot diameter) is preferably between 0.5 and 3.0, preferably between 1.0 and 2.0 (see in this respect also FIG. 4).

The final separation of the contour from the substrate can be effected by, after steps (a) to (d) (possibly also already during implementation of one of these steps), mechanical forces being exerted on the substrate (for example by means of a mechanical stamp) and/or thermal stresses being introduced into the substrate (for example by means of a CO₂ laser) in order to heat and cool again the substrate non-uniformly. As a result, between immediately adjacent extended portions of induced absorption or between immediately adjacent zones of internal damage, a crack formation in order to divide the substrate into a plurality of parts, i.e. for separating the contour can be effected. This crack formation should thereby be understood (in contrast to the depth crack formation induced in the direction of the substrate depth or that in steps (a), (b) and (d), as transverse crack formation, i.e. as a lateral crack formation in the substrate plane (corresponding to the course of the contour line, along which the contour is to be separated from the substrate).

It is thereby essential, in the case of this preferred procedure in steps (a), (b) and (d) that, per laser pulse (or per burst pulse), a laser beam focal line (and not merely a focal point which is not extended or only very locally) is produced. For this purpose, the laser lens systems illustrated also in detail subsequently are used. The focal line thus determines the zone of interaction between laser and substrate. If the focal line falls at least in portions (viewed in the depth direction) into the substrate material to be separated, then the laser parameters can be chosen such that an interaction with the material takes place, which produces a crack zone along the entire focal line (or along the entire extended portion of the laser beam focal line which falls into the substrate). Selectable laser parameters are for example the wavelength of the laser, the pulse duration of the laser, the pulse energy of the laser and also possibly the polarisation of the laser.

As a result of this preparation of the contour separation in steps (a), (b) and (d), it is made possible according to the invention to separate contours made of very thin glass substrates (glass substrates with thicknesses<300 μm, <100 μm or even <50 μm. This is effected without edges, damage, cracks, flaking or the like on the substrate (remains) which are left after separation of the contour so that complex aftertreatments are not required according to the invention. The zones of internal damage along the lines can thereby be introduced at high speeds (>1 m/s).

Further advantageously achievable features of the method according to the invention are described in the disclosure. There is thereby understood by a spiral very much in general (viewed in the substrate plane), a planar linear structure which is wound multiple times within itself and of almost any shape, which structure begins at one point (in the centre of the internal contour) and, with increasing number of windings, approaches the outer edge of the internal contour more and more and hence approximates to the latter (a spiral according to the invention is therefore not restricted to mathematical spirals in the narrower sense).

The disclosure describes further advantageous features of the invention. Any features can thereby be produced in any combination with each other. The laser properties described in the disclosure apply (provided nothing different is mentioned) likewise for the production and the beam guidance of the material-removing laser beam in the material removal step. With respect to the specific laser parameters in the material removal step which are produced advantageously, see however elsewhere in the disclosure.

It is possible to use the types of laser mentioned in the disclosure as material-removing laser by (in comparison with production of a large number of zones of internal damage with these types of laser) the lens construction being correspondingly adapted: no focal line lens system is used but instead a “normal” lens with e.g. 100 mm focal distance (preferably in the range between 70 mm and 150 mm). A galvanometer scanner set up with F-theta-lens is preferred.

Further possible lasers: Nd:YAG laser with 532 nm/515 nm wavelength. However, also a CO₂ laser with 9 to 11 μm wavelength together with a gas nozzle is very suitable.

It can prove to be favourable to vary, between step (a), on the one hand, and step(s) (b) and/or (d), on the other hand, e.g. the spacing between adjacent zones of internal damage. In particular increasing this spacing in step(s) (b) and/or (d) is advantageous compared with step (a) since a favourable crack formation and hence damage in the internal region of an internal contour thus takes place.

Parameters by way of example can be as follows:

• • For toughened glass (0.7 mm; DOL 40 μm): burst 2 pulses; 200 kHz repetition rate; 3.5 μm pulse spacing; 25 W laser power; numerical aperture lens system 0.1; focal line length 1.8 mm.
  • For untoughened glass (2.8 mm): burst 5 pulses, 100 kHz repetition rate; 5 μm pulse spacing, 50 W laser power; numerical aperture lens system 0.08; focal line length 2.8 mm.

Advantageous procedures for implementing the material removal step are described in the disclosure. For example a 20-times passage of the removal line for a glass substrate of thickness 0.7 mm is thereby effected in order to cut the removal line into the substrate material over the entire thickness of the substrate material.

In the vaporization of precipitation material procedure described herein, beams of all lasers mentioned in the present invention can be used as laser beams, with the exception of a CO₂ laser. In particular, a laser wavelength of 532 nm can be used. Polyoxymethylene (POM) can be used as precipitation material.

The mounting of the substrate can be ensured for example with the help of a clamping device with a depression as cavity. By means of the vapour pressure in the gas-sealed cavity, expulsion of the substrate piece separated by means of the separation line and possibly even expulsion of the thereafter still remaining remains of the contour still connected to the substrate is possible.

The disclosure advantageously describes materials which can be machined with the method according to the invention.

Devices according to the invention which are capable of implementing the methods according to the invention are described in the disclosure. A laser which is capable, according to the disclosure, of generating both the laser beam in steps (a), (b) and (d) and the material-removing laser beam for the material removal step is for example a 50 W picosecond laser.

According to the invention, it can be advantageous for the final separation of the contour to supply moisture to the substrate material after introduction of the large number of zones of internal damage. As a result of capillary forces, water is drawn into the damage zones and can induce stresses by means of linking up with open bonds in the glass structure (caused by the laser), which stresses help finally to form a crack. Hence controlled supply of the cut contours (internal and external contour) with water is possible, the impingement being able to be effected during or after the laser machining. Use of an evaporator in the device for producing a moist airflow and/or use of a moist substrate mounting or receiving means is possible. A water reservoir can be provided in the region of the contour line to be introduced.

The present invention of producing and separating a contour in or from a planar substrate has the following advantages in particular relative to the contour cutting methods known from the state of the art:

• • By combining the introduction of zones of internal damage, on the one hand (steps (a), (b) and possibly also (d)), and the material removal- and/or material deformation step (c), on the other hand, a very high separation quality can be achieved for contours: practically no break-outs occur, the cut edges on the substrate, after removal of the contour, have very low roughness and also high precision.
  • Internal contours shaped in almost any way (circular internal contours, oblong hole-shaped internal contours or any free form surfaces) can be separated with great precision according to the invention. A high resolution of structures of the internal contour is thereby possible.
  • The formation of stress cracks outside the internal contour (i.e. in the remaining substrate) is avoided.
  • The method is suitable not only for removing internal contours but also for separating external contours, which have very small radii or corners, with very good quality of the produced external edges on the remaining substrate. In particular, external contours which have undercuts (e.g. dovetail-shaped external contours) can be produced and separated with high quality.

BRIEF DESCRIPTION OF THE DRAWINGS

Subsequently, the present invention is described with reference to embodiments. The material removal- and/or material deformation step which is implemented here as material removal step is designated here in brief with (c). There are shown:

FIGS. 1A and 1B: The principle of positioning according to the invention of a focal line, i.e. the machining of the substrate material which is transparent for the laser wavelength based on induced absorption along the focal line in steps (a), (b) and (d).

FIG. 2: An optical arrangement which can be used according to the invention for steps (a), (b) and (d).

FIGS. 3A and 3B: A further optical arrangement which can be used according to the invention for steps (a), (b) and (d).

FIG. 4: A microscope image of the substrate surface (plan view on the substrate plane) of a glass disc machined according to step (a).

FIGS. 5A to 5D: Steps (a) to (d) which lead to removal of a circular internal contour from a substrate according to the invention.

FIG. 6: An example of step (d) according to the invention in which a stress-relieving spiral is produced as stress-relieving line portion.

FIG. 7: An example of separation according to the invention of an external contour from a substrate.

FIGS. 8A to 8C: Examples of different cut guidances for removing a circular internal contour.

FIGS. 9A and 9B: An example for implementing a material removal step.

FIG. 10: A sketch of a device according to the invention for producing and separating contours.

DETAILED DESCRIPTION

FIGS. 1A and 1B outline the basic procedure of steps (a), (b) and (d). A laser beam 3 which is emitted by the laser 12 (FIG. 10), not shown here, and which is designated on the beam input side of the optical arrangement 20 with the reference number 3a, is beamed onto the optical arrangement 20 of the invention. The optical arrangement 20 forms, from the radiated laser beam, on the beam output side over a defined extension region along the beam direction (length l of the focal line), an extended laser beam focal line 3b. Covering the laser beam focal line 3b of the laser radiation 3 at least in portions, the planar substrate 2 to be machined is positioned in the beam path after the optical arrangement. The reference number 4v designates the surface of the planar substrate orientated towards the optical arrangement 20 or the laser, the reference number 4r designates the rear-side surface of the substrate 2 which is normally parallel hereto and at a spacing therefrom. The substrate thickness (perpendicular to the surfaces 4v and 4r, i.e. measured relative to the substrate plane) is designated here with the reference number 10.

As FIG. 1A shows, the substrate 2 here is orientated perpendicular to the beam longitudinal axis and hence to the focal line 3b which is produced in space by the optical arrangement 20 behind the same (the substrate is perpendicular to the drawing plane) and, viewed along the beam direction, is positioned relative to the focal line 3b such that the focal line 3b, viewed in the beam direction, begins in front of the surface 4v of the substrate and ends in front of the surface 4r of the substrate, i.e. still inside the substrate. The extended laser beam focal line 3b hence produces (with suitable laser intensity along the laser beam focal line 3b which is ensured by the focusing of the laser beam 3 on a portion of the length l, i.e. through a line focus of length l) in the overlapping region of the laser beam focal line 3b with the substrate 2, i.e. in the material of the substrate which is covered by the focal line 3b, an extended portion 3c, viewed along the beam longitudinal direction, along which an induced absorption in the material of the substrate is produced, which induces a crack formation in the material of the substrate along the portion 3c. The crack formation is thereby effected not only locally but over the entire length of the extended portion 3c of the induced absorption (i.e. the zone of internal damage). The length of this portion 3c (i.e. ultimately the length of the overlapping of the laser beam focal line 3b with the substrate 2) is provided here with the reference number L. The average diameter or the average extension of the portion of the induced absorption (or of the regions in the material of the substrate 2 which are subjected to the crack formation) is designated here with the reference number D. This average extension D corresponds essentially here to the average diameter δ of the laser beam focal line 3b.

As FIG. 1A shows, substrate material which is transparent for the wavelength λ of the laser beam 3 is hence heated according to the invention by induced absorption along the focal line 3b. FIG. 1B shows that the heated material ultimately expands so that a correspondingly induced stress leads to the microcrack formation according to the invention, the stress being greatest on the surface 4v.

Subsequently, concrete optical arrangements 20 which can be used for producing the focal line 3b and also a concrete optical construction (FIG. 10) in which these optical arrangements can be used are described. All arrangements or constructions are thereby based on the above-described ones so that respectively identical reference numbers are used for components or features which are identical or correspond in their function. Subsequently, respectively only the differences are therefore described.

Since the separation surface leading ultimately to the separation is or should be of high quality according to the invention (with respect to breaking strength, geometric precision, roughness and avoidance of aftertreatment requirements), the individual focal lines 5-1, 5-2, . . . which are to be positioned along for example the contour line 5 on the surface of the substrate are produced as described with the subsequent optical arrangements (the optical arrangement is subsequently also termed alternatively laser lens system). The roughness is thereby produced in particular from the spot size or from the spot diameter of the focal line. In order to be able to achieve, with a given wavelength λ of the laser 12 (interaction with the material of the substrate 2), a low spot size of for example 0.5 μm to 2 μm, generally specific requirements are placed on the numerical aperture of the laser lens system 20. These requirements are fulfilled by the subsequently described laser lens systems 20.

In order to achieve the desired numerical aperture, the lens system must have, on the one hand, the required opening at a given focal distance, according to the known formulae of Abbé (N.A.=n sin (theta), n: refractive index of the glass to be machined, theta: half the opening angle; and theta=arctan (D/2f); D: opening, f: focal distance). On the other hand, the laser beam must illuminate the lens system up to the required opening, which is effected typically by beam expansion by means of expanding telescopes between laser and focusing lens system.

The spot size should thereby not vary too greatly for a uniform interaction along the focal line. This can be ensured for example (see embodiment below) by the focusing lens system being illuminated only in a narrow, annular region by the beam then opening and hence the numerical aperture of course changing only slightly as a percentage.

According to FIG. 2 (cut perpendicular to the substrate plane at the level of the central beam in the laser beam bundle of the laser radiation 12; here also, radiation of the laser beam 3 is effected perpendicular to the substrate plane so that the focal line 3b or the extended portion of the induced absorption 3c is parallel to the substrate normal), the laser radiation 3a emitted by the laser 3 is directed firstly onto a circular diaphragm 20a which is completely non-transparent for the laser radiation used. The diaphragm 20a is thereby orientated perpendicular to the beam longitudinal axis and centred on the central beam of the illustrated beam bundle 3a. The diameter of the diaphragm 20a is chosen such that the beam bundles (designated here with 3aZ) which are situated close to the centre of the beam bundle 3a or of the central beam impinge on the diaphragm and are absorbed completely by the latter. Merely beams situated in the external circumferential region of the beam bundle 3a (edge beams, designated here with 3aR) are not absorbed on the basis of the diaphragm size which is reduced in comparison with the beam diameter but rather pass through the diaphragm 20a at the side and impinge on the edge regions of the focusing optical element of the optical arrangement 20 which is configured here as a spherically ground, bi-convex lens 20b.

The lens 20b centred on the central beam is configured here deliberately as uncorrected, bi-convex focusing lens in the form of a normally spherically ground lens. In other words, the spherical aberration of such a lens is deliberately made use of. As an alternative thereto, aspherical lenses or multilenses which deviate from ideally corrected systems and have in fact no ideal focal point but rather form a pronounced longitudinally extended focal line of a defined length can be used (i.e. lenses or systems which have in fact no longer any individual focal point). The zones of the lens hence focus precisely as a function of the spacing from the centre of the lens along a focal line 3b. The diameter of the diaphragm 20a transversely relative to the beam direction is here approx. 90% of the diameter of the beam bundle (beam bundle diameter defined by the extension up to reduction to 1/e) and approx. 75% of the diameter of the lens of the optical arrangement 20. According to the invention, hence the focal line 3b of a non-aberration-corrected spherical lens 20 is used and was produced by stopping down the beam bundles in the centre. The section is represented in a plane through the central beam, the complete three-dimensional bundle is produced if the represented beams are rotated about the focal line 3b.

An improved optical arrangement 20 which can be used according to the invention is produced if this comprises both an axicon and a focusing lens.

FIG. 3A shows such an optical arrangement 20 in which, viewed in the beam path of the laser 12 along the beam direction, firstly a first optical element with a non-spherical free surface which is shaped to form an extended laser beam focal line 3b is positioned. In the illustrated case, this first optical element is an axicon 20c with 5° cone angle which is positioned perpendicular to the beam direction and centred on the laser beam 3. An axicon or cone prism is a special, conically ground lens which forms a point source on a line along the optical axis (or even annularly transforms a laser beam). The construction of such an axicon is basically known to the person skilled in the art; the cone angle here is for example 10°. The cone tip of the axicon thereby points in the opposite direction to the beam direction. In the beam direction at the spacing 21 from the axicon 20c, a second, focusing optical element, here a plano-convex lens 20b (the curvature of which points towards the axicon) is positioned. The spacing 21 at approx. 300 mm is chosen here such that the laser radiation formed by the axicon 20c impinges annularly on the externally situated regions of the lens 20d. The lens 20d focuses the annularly impinging radiation, on the beam output-side, at a spacing 22 of here approx. 20 mm from the lens 20d onto a focal line 3b of a defined length of here 1.5 mm. The effective focal distance of the lens 20d is here 25 mm. The annular transformation of the laser beam due to the axicon 20c is provided here with the reference number SR.

FIG. 3B shows the configuration of the focal line 3b or of the induced absorption 3c in the material of the substrate 2 according to FIG. 3A in detail. The optical properties of the two elements 20c, 20d and also the positioning of the same is effected here such that the extension 1 of the focal line 3b in the beam direction corresponds exactly to the thickness 10 of the substrate 2. Correspondingly, exact positioning of the substrate 2 along the beam direction is necessary in order, as shown in FIG. 3B, to position the focal line 3b exactly between the two surfaces 4v and 4r of the substrate 2.

According to the invention, it is hence advantageous if the focal line is formed at a specific spacing of the laser lens system and if the large part of the laser radiation is focused up to a desired end of the focal line. This can be achieved, as described, by a mainly focusing element 20d (lens) being illuminated only annularly on a desired zone, as a result of which the desired numerical aperture, on the one hand, and hence the desired spot size is produced, however, on the other hand, loses intensity after the desired focal line 3b of the dispersing circle over a very short distance in the centre of the spot since an essentially annular spot is formed. Hence the crack formation, in the sense of the invention, is stopped inside a short distance at the desired depth of the substrate. A combination of axicon 20c and focusing lens 20d fulfils this requirement. The axicon 20c hereby acts in two ways: by means of the axicon 20c, a usually round laser spot is transmitted annularly towards the focusing lens 20d and the asphericality of the axicon 20c has the effect that, instead of a focal point in the focal plane of the lens, a focal line outside the focal plane is formed. The length l of the focal line 3b can be adjusted via the beam diameter on the axicon 20c. The numerical aperture along the focal line can be adjusted in turn via the spacing 21 between the axicon 20c and the lens 20d and via the cone angle of the axicon 20c. In this way, the entire laser energy can hence be concentrated in the focal line 3b.

Should the crack formation (in the zone of internal damage) stop, in the sense of the invention, apart from the exit side of the substrate, then the annular illumination still continues to have the advantage that, on the one hand, the laser power is used as well as possible since a large part of the laser light remains concentrated at the desired length of the focal line and, on the other hand, by means of the annular illuminated zone together with the desired aberration adjusted by the other optical functions, a uniform spot size along the focal line can be achieved and hence a uniform separation process according to the invention along the focal line.

Instead of the plano-convex lens 20b illustrated in FIG. 3A, also a focusing meniscus lens or another more highly corrected focusing lens (aspherical, multilenses) can be used.

Borosilicate- or soda lime glasses 2 without other colouration (in particular with a low iron content) are optically transparent from approx. 350 nm to approx. 2.5 μm. Glasses are generally poor heat conductors, for which reason laser pulse durations of a few nanoseconds do not in fact allow any substantial heat diffusion out of a focal line 3b. Nevertheless, even shorter laser pulse durations are advantageous since, with sub-nanosecond- or picosecond pulses, a desired induced absorption can be achieved more easily via non-linear effects (intensity substantially higher).

For separation of planar glasses according to the invention, for example a commercially available picosecond laser 12 which has the following parameters is suitable: wavelength 1,064 nm, pulse duration of 10 μs, pulse repetition frequency of 100 kHz, average power (measured directly after the laser) of up to 50 W. The laser beam firstly has a beam diameter (measured at 13% of the peak intensity, i.e. 1/e² diameter of a Gaussian beam bundle) of approx. 2 mm, the beam quality is at least M²<1.2 (determined according to DIN/ISO 11146). With a beam expanding lens system (commercially available beam telescope according to Kepler), the beam diameter can be increased by the factor 10 to approx. 20-22 mm. With a so-called annular diaphragm 20a of 9 mm diameter, the inner part of the beam bundle is stopped down so that an annular beam is formed. With this annular beam, e.g. a plano-convex lens 20b with 28 mm focal distance (quartz glass with radius 13 mm) is illuminated. By means of the strong (desired) spherical aberration of the lens 20b, the focal line according to the invention is produced.

The theoretical diameter δ of the focal line varies along the beam axis, for this reason it is advantageous for the production of a homogeneous crack surface if the substrate thickness 10 is less here than approx. 1 mm (typical thicknesses for display glasses are 0.5 mm to 0.7 mm). With a spot size of approx. 2 μm and a spacing of spot to spot of 5 μm, a speed of 0.5 m/sec is produced, with which the focal line can be guided over the substrate 2 along the contour line 5 (cf FIG. 4). With 25 W average power on the substrate (measured following the focusing line 7), there results from the pulse train frequency of 100 kHz, a pulse energy of 250 μJ which can also be effected in a structured pulse (rapid train of individual pulses at a spacing of only 20 ns, so-called burst pulse) of 2 to 5 sub-pulses.

Untoughened glasses essentially have no internal stresses, for which reason the disruption zone which is still interlocked and connected by unseparated bridges still at first holds the parts together without external effect. If however a thermal stress is introduced, the contour 1 is finally completely separated and without further external introduction of force from the substrate 2. For this purpose, a CO₂ laser with up to 250 W average power is focused on a spot size of approx. 1 mm and this spot is guided at up to 0.5 m/s over the contour line 5, the crack lines 6 and possibly also the stress-relieving line 11 (cf. FIGS. 5A to 5D). The local thermal stress due to the introduced laser energy (5 J per cm of the lines) separates the contour 1 completely.

For separation in thicker glasses, the threshold intensity for the process (induced absorption and formation of a disruption zone by thermal shock) must of course be achieved via a longer focal line 3b. Hence higher required pulse energies follow and higher average powers. With the above-described lens system construction and the maximum available laser power (after losses due to the lens system) of 39 W on the substrate 2, the separation of approx. 3 mm thick glass is achieved. On the one hand, the annular diaphragm 20a is thereby removed and, on the other hand, the spacing of lens 20b to substrate 2 is corrected (nominal focal spacing increases in direction) such that a longer focal line 3b is produced in the substrate 2.

Subsequently, a further embodiment for separating toughened glass is presented.

Sodium-containing glasses are toughened by sodium being exchanged for potassium on the glass surface by immersion in liquid potassium salt baths. This leads to a considerable internal stress (compression stress) in a 5-50 μm thick layer on the surfaces, which in turn leads to higher stability.

Basically, the process parameters during separation of toughened glasses are similar to those with untoughened glasses of a comparable dimension and composition. However, the toughened glass can shatter very much more easily as a result of the internal stress and in fact as a result of undesired crack growth which is effected not along the lasered intended fracture surface 5 but into the material. For this reason, the parameter field for successful separation of a specific toughened glass is specified more tightly. In particular the average laser power and the associated cutting speed must be maintained very exactly and in fact as a function of the thickness of the toughened layer. For a glass with 40 μm thick toughened layer and 0.7 mm total thickness, there results with the above-mentioned construction for example the following parameters: cutting speed of 1 m/s at 100 kHz pulse train frequency, therefore a spot spacing of 10 μm, with an average power of 14 W. In addition, the step sequence (a) to (c) (preferably with (d)) for such glasses is particularly crucial in order to prevent undesired cracks and destruction in the remaining substrate 2.

Very thin toughened glasses (<100 μm) consist predominantly of tempered material, i.e. front- and rear-side are for example respectively 30 μm sodium-depleted and hence toughened and only 40 μm in the interior are untoughened. This material shatters very easily and completely if one of the surfaces is damaged. Such toughened glass films have to date not been machinable in the state of the art but are with the presented method.

Separation of this material according to the method of the invention is successful if a) the diameter of the focal line is very small, e.g. less than 1 μm, b) the spacing from spot to spot is low, e.g. between 1 and 2 μm, and c) the separation speed is high enough so that the crack growth cannot run ahead of the laser process (high laser pulse repetition frequency, e.g. 200 kHz at 0.2 to 0.5 m/s).

FIG. 4 shows a microscopic image of the surface of a glass disc machined according to the invention according to step (a). The individual focal lines or extended portions of induced absorption 3c along the contour line 5 which are provided here with the reference numbers 5-1, 5-2, . . . (into the depth of the substrate perpendicular to the illustrated surface) are connected along the line 5, along which the laser beam was guided over the surface 4v of the substrate, to form a separation surface by crack formation for separation of the substrate parts which is effected via the further steps according to the invention. Readily seen is the large number of individual extended portions of induced absorption 5-1, 5-2, . . . , the pulse repetition frequency of the laser, in the illustrated case, having been coordinated to the feed speed for moving the laser beam over the surface 4v such that the ratio α/δ of the average spacing a of immediately adjacent portions 5-1, 5-2, . . . and of the average diameter δ of the laser beam focal line is approx. 2.0.

FIGS. 5A-5D show, by way of example, the machining according to the invention of a 0.7 mm thick glass substrate 2 in plan view on the substrate plane.

As FIG. 5A shows, in the contour definition step (a), the laser beam 3 of a Nd:YAG laser with a wavelength lambda of 1,064 μm (the laser 12 is not shown here) is radiated vertically onto the substrate plane and guided along the contour line 5 which characterises the contour 1 to be produced. The contour 1 to be produced is here a circular internal contour which is intended to be removed from the substrate 2. The aim of the machining is hence the production of an exactly circular hole in the substrate 2. The circular internal contour 1 or the substrate material of the same can be destroyed during method steps (a) to (d) since the remaining substrate portions 2 represent the desired production product.

As FIG. 5A shows, due to the pulse operation of the laser 12 by means of the laser beam 3 along the contour line 5, a large number of individual zones 5-1, 5-2, . . . of internal damage is produced in the substrate material (portions of induced absorption along a portion which is extended, viewed in the beam direction, of the laser beam focal line produced by means of the laser 12). The individual zones 5-1, 5-2, . . . of internal damage are thereby produced as described for FIG. 4 (this applies also to the steps (d) and (b) which are also described subsequently).

After such zones of internal damage 5-1, 5-2, . . . have been produced over the entire circle circumference 5, a fracture line corresponding to the internal contour 1 to be separated has in fact been produced in the substrate, however the material of the internal contour 1, as described already, is not yet completely separated from the material of the remaining substrate portion 2. The further steps (b) to (d) now serve to separate completely the material of the internal contour 1 from the substrate 2 such that any damage (such as cracks, flaking and the like) in the remaining substrate material are avoided.

In order to achieve this, there is introduced firstly, in a stress-relieving step (d) subsequent to step (a), cf. FIG. 5B (in which the features already described in FIG. 5A are provided with identical reference numbers; this then also applies to the subsequent FIGS. 5C and 5D), a stress-relieving line portion 11 which approximates to the course of the contour line 5 (here by a constant spacing from the latter), is introduced concentrically within the contour line 5 and at a spacing from the latter, i.e. in the material of the internal contour 1. Introduction of the stress-relieving line portion 11 which is likewise circular here is thereby effected by means of the laser 12 with the same laser parameters as for the contour line 5 so that, along the complete circular circumference of the portion 11, respectively a large number of individual zones 11-1, 11-2, . . . of internal damage is produced in the substrate material. The introduction of these zones 11-1, 11-2, . . . is also effected as described for FIG. 4.

This step (d) serves to produce a stress reduction, i.e. latent stresses in the substrate material introduced during introduction of the contour line could otherwise lead to tearing of the entire substrate in the case of small contour radii and highly tempered glasses. This can be prevented by the additional cut of step (d) which is not however an absolute necessity. This step can have a spiral as shape but can also be configured as “circle-within-circle” which approximates to the contour line. The aim of this cut is to minimise the spacing of the stress-relieving line portion 11 relative to the target contour in order to leave behind as little material as possible and therefore to enable or to promote self-detachment. For example, values for the maximum approximation of the stress-relieving line portion 11 to the contour line 5 are here approx. 20 μm to 50 μm.

FIG. 5c shows the crack definition step (b) implemented according to the invention after the stress-relieving step (d). In this step, the laser beam 3 of the laser 12 is guided, just as in steps (a) and (d), over the substrate surface or the internal contour surface so that, here also, a large number of individual zones 6-1, 6-2, . . . of internal damage is introduced, as shown in FIG. 4, along the structures 6 inscribed into the internal contour 1.

As FIG. 5 shows, there are produced, in addition, a plurality of linear crack line portions 6a, 6b, . . . which begin at a place on the contour line 5, lead away from the contour line 5 respectively at an angle α of here 25° and lead into the contour 1 to be separated. Respectively exactly two crack line portions (for example the crack line portions 6a and 6b) thereby begin at one and the same place on the contour line 5 and extend in oppositely situated directions respectively at the angle α into the inner contour 1 until they cut the previously introduced stress-relieving line portion 11. The angle α is here the angle between the tangent to the contour line 5 at that place at which the two crack line portions, which lead from this place, in essentially opposite directions, into the material of the internal contour 1 (for example the portions 6a and 6b or also the portions 6c and 6d), begin, and the tangent to the respective crack line portion at this place (or the crack line portion itself since this coincides with the tangent thereof).

In the above-described way, there is produced, along the entire circumference of the contour line 5, a plurality of V-shaped crack lines 6V which consist respectively of precisely two crack line portions which begin at one and the same place on the contour line 5, lead away from the contour line 5 over the surface portions of the internal contour 1 which are situated between said contour line and the stress-relieving line portion 11, cut the stress-relieving line portion 11 and lead into the region of the internal contour 1 situated within the stress-relieving line portion 11. Both legs of one and the same V-shaped crack line 6V thereby lead along the tangent to the contour line 5 at the place of the tip of the respective crack line, viewed symmetrically to the normal, towards this tangent, i.e. on both sides of the normal, into the internal contour 1. Smaller angles α of for example α=10° or even larger angles of for example α=35° are possible according to the circular circumference of the lines 5 and 11 and also the spacing of these two circular lines from each other.

The crack line portions 6a, 6b, . . . need not thereby definitely, even if this is preferred, begin immediately at one place on the contour line 5 but rather can begin also slightly at a spacing from the contour line 5 at a place situated within the internal contour material 1 and can be guided beyond the stress-relieving line portion 11 into the material portion situated within the same (the angle α between the imaginary continued cut line of the respective crack line portion with the contour line 5, on the one hand, and the tangent to the contour line 5, on the other hand, is then calculated).

In the above-described way, preferably five to ten V-shaped crack lines along the circumference of the circular lines 5, 11 are produced.

The crack lines 6V or the crack line portions 6a, 6b, . . . of the same are thereby placed and orientated preferably such that the detachment behaviour is improved during and/or after the material-removing laser step (c). The material ring remaining after the material-removing laser step (c) is specifically segmented such that individual segments of the circular ring can be detached more easily. It is attempted to build up an internally directed stress into the V cuts so that the partial segments after the material-removing laser step (c) are pressed inwards as far as possible by themselves. These V cuts are however not an absolute necessity since the method according to the invention can also function without these.

It is hence essential that some of the ring material portions which are inscribed with the V-shaped crack lines into the material of the circular ring portion between the two structures 5 and 11 (here: the approximately triangular portions between the two legs of one and the same V-shaped crack line) could move towards the centre of the internal contour 1 (if they were already completely detached by means of the zones 6-1, 6-2, . . . ) without interlocking with adjacent ring material portions.

FIG. 5D finally shows the material removal step (c) after the crack definition step (b). (In FIG. 5D, merely three of the V-shaped crack lines introduced in step (b) are illustrated for reasons of clarity).

In step (c), a material-removing laser beam 7 produced by a laser 14, not shown here, is directed towards the substrate surface. In comparison with introduction of the large number of zones of internal damage in steps (a), (b), (d), as described for FIG. 4, the parameters of the material-removing laser beam 7 differ from the laser beam 3 as follows: a point focus or point damage with accompanying material removal is applied. Wavelength: between 300 nm and 11,000 nm; particularly suitable 532 nm or 10,600 nm. Pulse durations: 10 ps, 20 ns or even 3,000 μs.

As FIG. 5D shows, with the laser beam 7 within the stress-relieving line portion 11, a removal line 9 which extends here likewise annularly and along the entire circumference of the contour circle 5 or of the stress-relieving line circle 11 (shown here merely in sections) is inscribed into the material of the internal contour 1. In the radial direction (viewed towards the centre of the internal contour 1), the spacing of the removal line 9 from the stress-relieving line 11 is here approx. 25% of the spacing of the stress-relieving line 11 from the outwardly situated contour line 5. The spacing 8 of the removal line 9 from the contour line 5 is hence 1.25 times the spacing of the stress-relieving line 11 from the contour line 5. The removal line 9 is thereby introduced such that it still cuts (viewed from the centre of the internal contour 1) the inwardly situated ends of the crack line portions 6a, 6b, . . . .

After introducing the removal line along the entire circumference of the contour line 5 or of the stress-relieving line 11, the material portions situated inside the removal line 9 in the centre of the internal contour 1 are detached from the substrate 2 since, along the removal line 9, the substrate material is removed over the entire substrate thickness 10 (cf. FIG. 9). Hence there remain of the internal contour material 1 to be separated merely the ring portions situated between the removal line 9 and the contour line 5.

Between the edge at the removal line 9, on the one hand, and the contour line 5, on the other hand, approximately triangular ring portions are produced between the two legs of each V-shaped crack line (see reference number 1′) which are in fact interlocked still with the material of adjacent ring portions (and are characterised here as contour remains still to be separated and have the reference number 1r) but are able to be removed inwards without introducing stresses which possibly damage the material of the remaining substrate 2.

In the aftertreatment step which is not shown here (implemented after steps (a) to (d)), the remaining undesired contour remains 1r (which also comprise the stress-relieving portions 1′) are separated from the remaining substrate 2 by means of a mechanical stamp which is moveable perpendicular to the substrate plane.

FIG. 6 shows an alternative form of introducing a stress-relieving line portion 11 into the substrate material of the internal contour 1 of FIG. 5A to be separated. Instead of a single circumferential, circular stress-relieving line portion 11, also a stress-relieving spiral 11S which approximates to the course of the contour line 5, is guided from the centre of the internal contour 1, viewed radially outwards, wound within itself and turning approx. 3.5 times here can be inscribed into the material of the internal contour 2 to be separated.

As FIG. 7 shows, the present invention can be used not only for separating closed internal contours 1 from a substrate 2 but also for separating complexly-shaped external contours 1, the shape of which (cf. for example the dovetail-shaped portion of the contour line 5 in FIG. 7) is such that the external contour 1 of the substrate 2 cannot be produced with methods known from the state of the art without introducing stress cracks into the remaining substrate material 2. The angle α of the two oppositely situated legs of the V-shaped crack lines 6V-1, 6V-2, . . . which are situated between the contour line 5, on the one hand, and the removal line 9, on the other hand, is here 10°. In FIG. 7, identical or corresponding features designate otherwise identical reference numbers as in FIGS. 5A-5B. The substrate thickness perpendicular to the substrate plane is characterised with the reference number 10. The substrate surface orientated towards the incident laser radiation 3, 7 with the reference number 4v (substrate front-side), the oppositely situated substrate surface (substrate rear-side) with the reference number 4r.

As FIG. 7 shows, introduction of a stress-relieving line portion 11 which approximates to the course of the contour line 5 is hence not absolutely necessary.

The invention can hence be used in particular also for separating contours with undercuts.

FIGS. 8A-8C show several different possibilities of how crack line portions 6a, 6b, . . . , which differ along the course of the contour line 5, begin respectively essentially at the contour line 5 and lead into the material of the contour 1 to be separated, can be produced: FIG. 8A shows V-shaped standard crack lines (see also FIG. 5C). FIG. 8B shows V-shaped multiple crack lines along the contour line course 5 in which respectively adjacent V-shaped crack lines intersect at the legs orientated towards each other. FIG. 8C shows open crack lines due to introduction respectively of only one leg of a V-shaped crack line.

FIG. 9 shows how, with an additional precipitation material 18 (here: polyoxymethylene), the inwardly situated material portion of an internal contour 1 to be separated, which is completely separated from the substrate 2 or from the contour remains 1r after introducing the removal line 9 (possibly also with parts of the contour remains 1r still adhering undesirably to the substrate 2), can be expelled. Identical reference numbers again designate in FIG. 9 (and also in FIG. 10) the features of the invention described already under these reference numbers.

As FIGS. 9A-9B show, the beam power, which is high compared with the laser beam 3, of the material-removing laser beam 7 is coupled via a (second, cf. FIG. 10) beam-guiding optical unit 21 onto the substrate 2. The substrate 2 is mounted in a clamping device 16 (e.g. so-called chuck) such that, in a region below the internal contour 1 to be separated, a gas-sealed cavity 17 is configured on the substrate rear-side 4r.

(“Above” is here the substrate front-side 4v which is orientated towards the incident laser beam). Into this cavity 17, the precipitation material 18 was introduced in advance and now is vaporised at the beginning of the illustrated material removal step (c) by focusing the laser beam 7 by means of the optical unit 21 through the substrate 2 into the cavity 17 (FIG. 9A). As a result of the laser beam-caused vaporisation, the vaporised precipitation material precipitates on the portion of the substrate rear-side 4r which is situated in the cavity 17 and forms (FIG. 9B) on at least one surface of the substrate rear-side 4r which corresponds to the internal contour 1 to be separated, a coupling layer 18′ which improves coupling of the laser beam 7 into the substrate material. Vaporisation of the material 18 for precipitation on the rear-side surface 4r is implemented. Since the material of the substrate 2 is transparent for the laser radiation λ, the material of the layer 18′ is however opaque for λ, coupling of the beam 7 into the substrate material is thus improved.

Subsequently, the laser radiation 7 is focused 15 by the optical unit 21 and through the substrate onto the rear-side surface 4r (cf. FIG. 9B). Corresponding to the geometry characterising the removal line 9, the focal point 15 of the laser radiation 7 is guided by multiple passage of the beam 7 along the line 9 successively from the substrate rear-side 4r towards the substrate front-side 4v in order to remove in succession the substrate material along the removal line 9, viewed over the entire substrate thickness 10, or to vaporise it as a result of the high laser energy which is introduced. After the large number (e.g. 15 times) of passages guided along the contour of the removal line 9 with the focal point 15 moving increasingly from the rear-side 4r to the front-side 4v, finally the material of the internal contour 1 which is situated inside the removal line 9 (which is illustrated here for simplified representation merely once and in the centre above the cavity 17) is detached and expelled upwards by the vapour pressure prevailing in the cavity 17. With sufficiently high vapour pressure in the cavity 17, also the separation of the undesired contour remains 1r can be assisted by this (cf. FIG. 5D).

FIG. 10 illustrates a device according to the invention for implementing the method according to the invention, which is provided with a beam producing- and beam-forming arrangement 19 configured in a common laser head. The unit 19 comprises the two lasers 12 (for production of the laser beam 3 which produces the individual zones of internal damage with lower laser intensity) and 14 (for producing the material-removing laser beam 7 of higher intensity) and also two beam-guiding optical units 20 and 21 which have respectively a galvanometer scanner connected subsequent to an F-theta lens for beam deflection (the construction of such optical units is known to the person skilled in the art). The laser radiation 3 of the laser 12, focused via the F-theta lens and the galvanometer scanner of the unit 20, is hence guided towards the surface of the substrate 2 and, for producing the contour line 5, is suitably deflected by means of the galvanometer scanner. Correspondingly, the laser radiation 7 of the laser 14, focused via the F-theta lens and the galvanometer scanner of the unit 21, is imaged on the surface of the substrate 2 and is deflected in order to produce the removal line 9 by the galvanometer scanner of the unit 21.

Alternatively, also stationary lens systems can be used instead of using moving lens systems (then the substrate is moved).

A central control unit which is configured here in the form of a PC 22 with suitable memories, programmes etc. controls the beam production, beam focusing and beam deflection by means of the unit 19 via a bidirectional data- and control line 23.

Differences in the beam-guiding lens systems 20 and 21 for producing the two different laser beams 3 and 7 are as follows: the laser beam 7 is guided towards the surface in comparison to the beam 3, e.g. with a corrected F-theta lens, which leads to the formation of a point focus. The focal distance of the lens for the beam 7 is significantly greater than for the beam 3, e.g. 120 mm in comparison with 40 mm.

Claims

1. A device for producing a contour (1) in a planar substrate (2) and for separating the contour (1) from the substrate (2), in particular for producing an internal contour (1) in the planar substrate (2) and for removing the internal contour (1) from the substrate (2), comprising:

a central control unit (22);

a beam-producing- and beam-forming arrangement (19) which is configured such that beam production, beam focusing and beam deflection is controlled with the central control unit (22) to perform:

a contour definition step (a) wherein a laser beam (3) is guided over the substrate (2) along a contour line (5) defining the contour (1) to be produced, and producing a plurality of individual zones (5-1, 5-2, . . . ) of internal damage in the substrate (2) material; and

a material removal- and/or material deformation step (c) performed after the contour definition step (a),

wherein, the material removal step comprises (i) a laser beam (7) directed towards the substrate (2) surface that inscribes a removal line (9) through a thickness (10) of the substrate (2) and within the contour (1) allowing for a portion of the substrate (2) to become detached, and (ii) a process gas directed towards the substrate via a gas nozzle, and

wherein, the material deformation step comprises a laser beam impinging the substrate (2) to thermally deform portions of the substrate (2) within the contour (1) thus causing the contour (1) to detach from the substrate (2); and

a crack deformation step (b), which is performed before the material removal- and/or material deformation step (c) and after the contour definition step (a), wherein the laser beam (3) is guided over the substrate (2) and produces a plurality of individual zones (6-1, 6-2, . . . ) of internal damage in the substrate material to form a plurality of crack line portions (6a, 6b, . . . ) that lead away from the contour line (5) at an angle α>0° and into the contour (1) to be separated;

wherein the beam-producing- and beam-forming arrangement (19) comprises:

a first laser (12) producing the laser beam (3) to be guided in the contour definition step (a) and in the crack deformation step (b), wherein the laser beam (3) forms a laser beam focal line via an optical assembly positioned in a beam path of the first laser (12), the optical assembly comprising: a first focusing optical element with spherical aberration configured to generate the laser beam focal line, wherein the first focusing optical element is an axicon and a second focusing optical element spaced a distance of about 300 mm apart from the first focusing optical element, wherein the second focusing optical element is a plano-convex lens, wherein the second focusing element is spaced a distance of about 20 mm from the planar substrate (2), wherein the average diameter δ of the laser beam (3), when impinging on the irradiated surface of the substrate (2) is between 0.5 μm and 5 μm, and a pulse repetition frequency of the first laser (12) producing the laser beam (3) is between 10 kHz and 1,000 kHz, and the first laser (12) is operated as a burst pulse laser, and the average laser power of the first laser (12) is between 10 watts and 100 watts;

a second laser (14) producing the material-removing laser beam (7) to be guided and/or to be radiated in the material removal- and/or material deformation step (c);

a first beam-guiding optical unit (20) with which, in the contour definition step (a) and in the crack deformation step (b), the laser beam (3) produced with the first laser (12) can be guided over the substrate (2), wherein the first beam-guiding optical unit (20) comprise a first F-theta lens, and

a second beam-guiding optical unit (21) with which, in the material removal- and/or material deformation step (c), the laser beam (7) produced with the second laser (14) can be guided over the substrate (2) and/or radiated onto the substrate (2), wherein the second beam-guiding optical unit (21) comprises a second F-theta lens having a focal distance that is greater than the focal distance of the first F-theta lens.

2. The device of claim 1,

wherein, the material removal- and/or material deformation step (c) is performed after the contour definition step (a) and wherein the material-removing laser beam (7) is guided over the substrate (2) along the removal line (9) which extends along the contour line (5) but at a spacing (8) from the latter and also in the contour (1) to be separated, and the substrate material is removed over the entire substrate thickness (10).

3. The device of claim 1,

in the material deformation step, the laser beam is a CO₂ laser beam that plastically deforms portions of the substrate (2).

4. The device of claim 1,

the beam-producing- and beam-forming arrangement (19) is further configured to perform:

an after treatment step that is performed after the material removal- and/or material deformation step (c), to remove remains (1r) of the contour (1) from the substrate (2);

the after treatment step comprises a thermal treatment of the contour remains (1r) that includes local non-homogenous heating by guidance of a CO₂ laser beam, at least in portions, over the contour line (5) and/or the crack line portions (6a, 6b, . . . ).

5. The device of claim 1,

the substrate is transparent or essentially transparent to the wavelength of the material-removing laser beam (7);

the material-removing laser beam (7) is focused through the substrate (2) into a focal point (15) situated on a rear-side (4r) of the substrate (2), which rear-side (4r) is oriented away from a front-side (4v) of the substrate (2) facing the incident laser beam (7); and

the material-removing laser beam (7) is guided several times through the removal line (9) with successive displacement of the focal point (15) from the substrate rear-side (4r) towards the substrate front-side (4v) in order to remove the substrate material over the entire substrate thickness (10).

6. The device of claim 5 further comprising:

a mounting (16) including a cavity (17) with a precipitation material (18) within the cavity, such that when the substrate (2) is mounted with the contour (1) to be separated and disposed between the substrate rear-side (4r) and the mounting (16), the cavity (17) is gas-sealed; and

the beam-producing- and beam-forming arrangement (19) is further configured to focus the laser beam (3) or laser beam (7) into the cavity (17) to vaporise the precipitation material (18).

7. A glass substrate cutting device comprising:

a first laser configured to emit laser beams through an optical arrangement and toward a planar surface of the glass substrate that faces the emitted laser beams;

the laser beams having a wavelength to which the glass substrate is essentially transparent; and

the optical arrangement manipulating the laser beams to have a focal line that falls within the glass substrate, wherein the first laser is a pulsed laser, and the laser beams that the laser is configured to emit have a pulse duration of greater than 100 ps, the optical arrangement comprising: a first focusing optical element with spherical aberration configured to generate the laser beam focal line, wherein the first focusing optical element is an axicon and a second focusing optical element spaced a distance of about 300 mm apart from the first focusing optical element, wherein the second focusing optical element is a plano-convex lens, wherein the second focusing element is spaced a distance of about 20 mm from the glass substrate;

a second laser configured to emit laser beams toward the planar surface of the glass substrate that faces the emitted laser beams, the laser beams of the second laser having a higher intensity than the laser beams of the first laser and a focused beam diameter;

a first beam-guiding optical unit with which the laser beams produced with the first laser can be guided over the substrate, wherein the first beam-guiding optical unit comprise a first F-theta lens;

a second beam-guiding optical unit with which the laser beams produced with the second laser can be guided over the substrate, wherein the second beam-guiding optical unit comprises a second F-theta lens having a focal distance that is greater than the focal distance of the first F-theta lens; and

a controller in communication with the first laser and the second laser, the controller configured to cause the first laser to emit laser beams toward the glass substrate,

to produce successive zones of internal damage in the glass substrate to define a contour line inscribed into the glass substrate such that, after the definition of the contour line, an inner contour portion of the glass substrate disposed at one side of the contour line remains connected to an external contour portion of the glass substrate disposed at another side of the contour line;

to produce successive zones of internal damage in the glass substrate to define a plurality of crack line portions, each of which begin at a place on the contour line and lead away from the contour line at an angle into the inner contour portion of the glass substrate;

and to cause the second laser to emit laser beams toward the glass substrate,

along the contour line but at a spacing therefrom and at the internal contour portion of the glass substrate to heat portions of the internal contour portion to cause a plastic deformation thereof that forms a gap between the internal contour portion and the external contour portion, resulting in separation of at least a portion of the internal contour portion from the remainder of the glass substrate; or

to form a removal line inscribed into the glass substrate at the internal contour portion that intersects, viewed from the internal contour portion, inwardly situated ends of the crack line portions, resulting in separation of at least a portion of the internal contour portion from the remainder of the glass substrate.

8. The glass substrate cutting device of claim 7,

the first laser positioned relative to the planar surface of the glass substrate such that the successive zones of internal damage that define the contour line extend into the glass substrate at an angle relative to the planar surface that is not perpendicular to the planar surface.

9. The glass substrate cutting device of claim 7,

the first laser is a pulsed laser and emits laser beams with repetition frequency between 10 kHz and 1,000 kHz;

the focal line having an average spot diameter of between 1 μm and 3 μm; and

each of the successive zones of internal damage has a center, and there is an average spacing distance between the center of successive zones of internal damage, with the ratio of the average spacing distance to the average spot diameter being between 1.0 and 2.0.

10. The glass substrate cutting device of claim 7,

the optical arrangement includes a circular diaphragm that is completely non-transparent to the wavelength of the laser beams and a focusing optical element;

the circular diaphragm sized and positioned to absorb a center portion of the laser beams but not a circumferential edge portion of the laser beams; and

the circumferential edge portion of the laser beams impinging on an edge region of the focusing optical element, which focuses the laser beams into the focal line.

11. The glass substrate cutting device of claim 7,

the optical arrangement includes an axicon and a focusing lens spaced a distance from the axicon;

the axicon having a cone angle which is positioned perpendicular to, and centered on the laser beam; and

the axicon manipulating the laser beam to impinge annularly on externally situated regions of the focusing lens, which focuses the laser beam into the focal line.

12. The glass substrate cutting device of claim 7,

the controller further configured to cause the laser to emit laser beams to produce successive zones of internal damage in the glass substrate to define a stress-relieving line portion inscribed into the glass substrate within the internal contour portion at a spacing of 20 μm to 50 μm from the contour line.

13. The glass substrate cutting device of claim 7 further comprising:

an ultrasonic actuator in communication with the controller, and configured to contact the internal contour portion of the glass substrate; and

the controller further configured to cause the ultrasonic actuator to vibrate at a frequency between 5 kHz and 40 kHz, after the controller has finished causing the first laser and the second laser to emit their respective laser beams onto the glass substrate, resulting in separation of at least a portion of the internal contour portion from the remainder of the glass substrate.